lm genetica e biologia molecolare nella ricerca di base e
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Gene Therapy
LM Genetica e Biologia molecolare nella Ricerca di Base e Biomedica aa 2014/2015
Prof. Isabella Saggio
Students: Del Giudice Simona Parisi Sofia Fioretti Elena Larivera Simone
Tutor La Torre Mattia
Group of rare and lethal conditions in which the infants die from an array of infections associated with a lack of lymphocytes in the blood.
SCID “Severe Combined Immunodeficiency”
adapted from: http://www.geneticsandsociety.org/article.php?id=3840
adapted from: http://www.saggiolab.com/who-else-for-students/
X-Linked SCID (50% of all SCID cases)
• IL2RG gene mapped to chromosome Xq13.1
• gamma c = common subunit of different interleukin receptors involved in growth and d i f f e r e n t i a t i o n o f lymphocytes.
X- SCID IS CAUSED BY INACTIVATING MUTATIONS IN IL2RG GENE
• IL2RG gene encodes the interleukin 2 r e c e p t o r c o m m o n gamma chain
adapted from: http://learn.genetics.utah.edu/content/disorders/singlegene/scid/
IL2RG mutant absence of signal cytokine activation X-SCID
1°Gene Therapy clinical trial for X-SCID Ca
vazz
ana-
Calv
o et
Al.
2000
Side effects
Main issue: Insertional Mutagenesis
10 children were treated with Ex vivo gene therapy. Transduction of CD34+ bone-marrow cells, using MoMLV for delivering wt IL2RG gene.
OUR PROPOSAL To overcome the insertional mutagenesis we propose:
Using gene editing tool RGENs (RNA guided engineered
nucleases) to reach site-specific integration of IL2RG wt gene into “safe harbor” (AAVS1 locus) in human HSCs.
Transduction of X-SCID hHSCs with IDLVs vectors for delivering wild-type IL2RG gene and Cas9/Crispr system.
Cas9/CRISPR system allows a site-specific integration of the therapeutic gene in A AVS1 locus to rescue immune system function.
adapted from: http://www.hematology.org/Thehematologist/Diffusion/3166.aspx
RNA - guided engineered nucleases (RGENs)
• Derived from bacterial CRISPR-Cas 9 system • Produce DSBs and enhance HDR efficiency in a specific way • Work as monomer • Low cytotoxicity • Convenient to produce
gRNA directs Cas9 nuclease on a 20 bp complementar DNA sequence. Cas9 perfoms DSBs that trigger endogenous DNA repair system resulting in a targeted genome modification.
adapted from: http://www.systembio.com
IDLVs VECTORS
FEATURES • HIV-1 based lentiviral vector (third generation) carrying a class I IN mutation in the D64V region of the catalytic domain, resulting in an inhibition of vector’s integration. • Possibility to provide a site specific integration in the genome through RGENs. • Possibility of use in ex vivo experiment without forcing cells replication.
5’LTR Ψ RRE cPPT Cas9 Puro MSCV H1
Ψ 5’LTR RRE cPPT IL2RG WPRE
WPRE
IDLV vector to deliver IL2RG
gRNA SIN 3’LTR T2A
GFP
AAVS1 HA Left
IDLV vector to deliver Cas9-CRISPR system T2A
T2A MSCV SIN 3’LTR
AAVS1 HA Right
Expression cassette
IDLVs PRODUCTION
Adapted from http://www.alstembio.com/virus-production/Lentiviral-packaging-mix
Cells HEK 293T are transiently transfected by: 1. Expression plasmid 2. Packaging plasmid 3. Pseudotyping plasmid 4.Plasmid containing rev gene.
Ultra – centrifugation to obtain supernatant containing the lentiviral particles.
p24ELISA assay to estimate the titer of the lentiviral vectors within supernatant.
AAVS1 Locus as “Safe Harbor”
Different studies showed the safe, stability and robustness of transgene expression after insertion in AAVS1 of human stem cells (iPSs, hHSCs).
DOI
:10.
1038
/NM
ETH
.167
4
Luigi Naldini, Pietro Genovese et AL., nature13420, 2014
AAVS1 is a common integration site of the human non pathogenic adeno-associated virus, found between exon 1 and intron 1 of protein phosphatase 1 regulatory subunit 12C (PPP1R12C) gene, located in chromosome 19.
Transgene’s insertion at the AAVS1 locus revealed no upregulation in gene expression of flanking genes.
IN VITRO EXPERIMENT
IN VITRO MODEL:
-‐ Human Hematopoietic Stem Cells (HSCs) bone marrow-‐derived from X-‐SCID infants
hHSCs
IDLV Cas9 + IDLV IL2RG
1. TRANSDUCTION
UNT IDLV Cas9 + empity IDLV
2. SELECTION OF POSITIVE TRANSDUCED CELLS USING PUROMYCIN
4. INSERTION’S SITE CONTROL THROUGH LAM - PCR
3. ISOLATION AND PROPAGATION OF SINGLE COLONIES
5. LAM PCR POSITIVE CELLS ARE PROPAGATED AS A CLONE
IL2RG EXPRESSION CHECK
β-actin
WESTERN BLOT for IL2RG in hHSCs
IL2RG
RT qPCR for IL2RG in hHSCs
0
10
20
30
mR
NA
rel
ativ
e ex
pres
sion
IN VITRO EXPERIMENT
VIABILITY ASSAY (MTT)
0
25
50
100
75
% o
f cel
ls s
urvi
val
IN VITRO EXPERIMENT FUNCTIONAL ASSAY
Induction of hHSCs’ differentiation adding specific growth and differentiation factors.
FLOW CYTOMETRY
using different surface markers to evaluate the presence of mature differentiated subtypes of lymphocytes
0
2
4
6
8
10
12 CD34-‐
CD34+ CD133-‐
CD34+ CD133+
CD34+CD133+CD90+
% o
f sub
popu
lati
ons
Adapted from: Luigi Naldini, Pietro Genovese et AL., nature13420, 2014
IN VIVO EXPERIMENTS
IN VIVO MODEL: NOD SCID gamma (NSG) Mice
• Albino, viable, fertile, normal size, do not display any abnormalities • Lack mature T cell, B cells and NK cells • Deficient in cytochine signaling • Abnormal immune system organ morphology
• Resistant to lymphoma development
• Support engraftment of hHSCs
• Median survival time 89 weeks
http://jaxmice.jax.org
IN VIVO EXPERIMENTS
1. Transplantation of gene-targeted CD34+ cells in NSG mice
2. Isolation of engrafted GFP + cells from mice’s bone marrow and blood by FACS
NSG Mice
Injection of IL2RG targeted CD34+ cells
0
Injection of tetanus vaccine
15 16
Isolation of engrafted GFP+ cells, Immunofluorescence assays Western blot and RT qPCR
Weeks after transplant
ELISA assay
18
3. Characterization of engrafted GFP + cells
Evaluate the repopulation of immune system To control IL2RG expression
IMMUNOFLUORESCENCE of GFP + cells WESTERN BLOT of GFP + cells
RT qPCR of GFP + cells
Evaluation through injection of tetanus vaccine
IN VIVO EXPERIMENTS Does our strategy work?
Do Mice rescue a normal phenotype with functional immune system ?
FUNCTIONAL ASSAY
Perform an ELISA assay to verify the presence of anti-tetan antibodies
NC
+
NC = negative control + = test positive S = sample UNT = untreated
FUTURE PERSPECTIVES
Perform a clinical trial
Explant of CD34+ cells from x-SCID infants
Targeted insertion of IL2RG wt gene using RGENs tool and IDLVs vectors
Characterization and functional assays of treated cells
In vitro propagation of positive treated cells
Trasplantation in infants
COSTS & TIME • LENTI – Smart TM NIL ( InvivoGen ) + Additional materials *
• LAM PCR: - Taq DNA polymerase (Qiagen)* - dNTPs (Fermentas)* - Oligonucleotides and primers MWG Biotech* - Magnetic particles: Dynabeads M--‐280 Streptavidin (Dynal) (Lifetechnologies) 452 $ - Kilobase binder kit (Dynal) (Lifetechnologies) 417 $ - Klenow polymerase (Roche) 109 $ - Hexanucleotide mixture (50 reactions) (Roche) 88 $ - Restriction endonuclease(s) and incubation buffer(s) (New England Biolabs)* - Fast - Link DNA ligation kit (Epicentre) 142 $ - T4 DNA Ligase (New England Biolabs) 62 $ - Spreadex EL1200 precast gel (Elchrom Scientific)* - QIAquick PCR purification kit (Qiagen)* - DNA extraction kit (Qiagen) • TaqMan (Applied Biosystems) 111$ • NSG Mice ( The Jackson Laboratry) 161$ per mouse • Stabulation 700 $ per month • Tetanus’ Vaccine (Sanofi Pasteur MSD) 10,20 $ per dose • ELISA Kit for Tetan’s Vaccine (BioCompare) 247 $ • Anti – IL2RG Antibody host mouse (Sigma-Aldrich) 386 $ • Secondary Anti – Mouse Antibody (Sigma-Aldrich) 237 $ • Antibody for specific sufrace markers of HSCs Cells and their progeny host rabbit (Bioss) * • Secondary Anti – Rabbit antibody (Pierce)* • FACS Kit (BD Bioscience)* • MTT Cell Proliferation Assay Kit (1000 Assays) (Life technologies)*
TIME: predict 30 months with an amount of 20000/30000$ the possibility of collaboration with other laboratories could decrease costs
*Contact distributor
REFERENCES - RNA-Guided Human Genome Engineering via Cas9, Prashant Mali et
Al., Science. 2013 February 15; 339(6121): 823–826. doi:10.1126/science.1232033.
- Robust, Persistent Transgene Expression in Human Embryonic
Stem Cells Is Achieved with AAVS1-Targeted Integration Joseph R. Smith et Al. STEM CELLS 2008;26:496–504.
- Gene Therapy of Human Severe Combined Immunodeficiency
(SCID)-X1 Disease, Marina Cavazzana-Calvo et al. Science 288, 669 (2000).
- Targeted genome editing in human repopulating haematopoietic stem cells. Pietro Genovese, Luigi Naldini et Al., 10.1038/nature13420 (2014).
- 20 years of gene therapy for SCID. Alain Fischer, Salima Hacein-Bey-Abina & Marina Cavazzana-Calvo. 2010 Nature America, Inc.
- BONE MARROW (HEMATOPOIETIC) STEM CELLS. Jos Domen, Amy Wagers and Irving L. Weissman, in Stem Cell Information. Bethesda, MD: National Instituite of Health, U.S. Department of Health and Human Services, 2011.
- Design and Potential of Non-Integrating Lentiviral Vectors. Aaron Shaw and Kenneth Cornetta, Biomedicines 2014, 2 , 14-35; doi:10.3390/biomedicines2010014.
- Hematopoietic Stem Cell Expansion and Gene Therapy, Korashon Lynn Watts et Al. Cytotherapy. 2011 November ; 13(10): 1164–1171. doi:10.3109/14653249.2011.620748.
- Gene editing in human stem cells using zinc finger nucleases and
integrase-defective lentiviral vector delivery . Angelo Lombardo et Al., 28 October 2007; doi:10.1038/nbt1353
- Insertional oncogenesis in 4 patients after retrovirus-mediated gene therapy of SCID-X1, Salima Hacein-Bey-Abina et Al., The Journal of Clinical Investigation, Volume 118 Number 9 September 2008.
- Lentiviral vectors with a defective integrase allow efficient and sustained transgene expression in vitro and in vivo. Ste´ phanie Philippe et Al., 17684–17689 PNAS November 21, 2006 vol. 103 no. 47
- Site-specific integration and tailoring of cassette design for sustainable gene transfer. Angelo Lombardo, Luigi Naldini et Al., DOI:10.1038/NMETH.1674, 2011 Nature America.
- Targeted transgene insertion into the AAVS1 locus driven by baculoviral vector-mediated zinc finger nuclease expression in human-induced pluripotent stem cells, Felix Chang Tay et Al.. J Gene Med 2013; 15: 384–395.
- Utilization of the AAVS1 safe harbor locus for hematopoietic specific transgene expression and gene knockdown in human ES cells. Amita Tiyaboonchai et Al., Stem Cell Research (2014) 12, 630–637.
- CRISPR-Cas systems for editing, regulating and targeting genomes, Jeffry D Sander & J Keith Joung, March 2014; doi:10.1038/nbt.2842.
- A guide to genome engineering with programmable nucleases, Hyongbum Kim and Jin-Soo Kim doi:10.1038/nrg3686, Published online 2 April 2014 .